Genetic and epigenetic effects of environmental arsenicals

Environmental arsenic compounds and their methylated metabolites do not form adducts with DNA, but do cause oxidative DNA damage. Chromosome aberrations are seen at toxic concentrations. Genetic effects that occur at non-toxic concentrations include aneuploidy, comutagenesis (resulting from indirect effects on DNA repair), and delayed mutagenesis (probably secondary to aneuploidy and/or epigenetic effects). Effects of trivalent arsenicals on poly(ADP ribose) polymerase and P53 activation may mediate effects on DNA repair and aneuploidy. A growing literature points to the epigenetic effects of arsenic compounds in cells and in vivo. A review of the current literature on DNA methylation, histone modifications and microRNA effects is presented.     

The role of DNA polymerases alpha, beta and gamma in nuclear DNA synthesis.

The effects of the inhibitors 2'3' dideoxythymidine triphosphate (ddTTP) and 1-beta-D-arabinofuranosyl cytosine triphosphate (araCTP) on DNA synthesis in isolated S-phase HeLa S3 nuclei have been examined. These effects are compared with the effects of the same inhibitors in partially purified preparations of DNA polymerases alpha and beta. The effect of ddTTP on partially purified DNA polymerase gamma was also tested. DNA polymerases beta and gamma were very sensitive to ddTTP whereas DNA polymerase alpha and DNA synthesis in isolated nuclei were quite resistant. The synthesis and subsequent ligation of primary DNA pieces ('Okazaki fragments') were not affected by the presence of this inhibitor. DNA synthesis in isolated nuclei and DNA polymerase alpha activity were very sensitive to araCTP whereas DNA polymerase beta was almost totally resistant to the inhibitor. The results indicate a major role for DNA polymerase alpha in DNA replication.     

Site-specific DNA cleavage by vaccinia virus DNA topoisomerase I. Role of nucleotide sequence and DNA secondary structure.

Cleavage of linear duplex DNA by purified vaccinia virus DNA topoisomerase I occurs at a conserved sequence element (5'-C/T)CCTT decreases) in the incised DNA strand. Oligonucleotides spanning the high affinity cleavage site CCCTT at nucleotide 2457 in pUC19 DNA are cleaved efficiently in vitro, but only when hybridized to a complementary DNA molecule. As few as 6 nucleotides proximal to the cleavage site and 6 nucleotides downstream of the site are sufficient to support exclusive cleavage at the high affinity site (position +1). Single nucleotide substitutions within the consensus pentamer have deleterious effects on the equilibria of the topoisomerase binding and DNA cleavage reactions. The effects of base mismatch within the pentamer are more dramatic than are the effects of mutations that preserve base complementarity. Competition experiments indicate that topoisomerase binds preferentially to DNA sites containing the wild-type pentamer element. Single-stranded DNA containing the sequence CCCTT in the cleaved stand is a more effective competitor than is single-stranded DNA containing the complementary sequence in the noncleaved strand.     

In vitro assessment of the toxicity of metal compounds

A review has been compiled illustrating the directions taken in examining the genotoxic effects of metals and their compounds centering only on those studies pertaining to effects of metals and their compounds on DNA structure and function, such as the induction of DNA strand breaks, production of DNA-protein crosslinks, induction of chromosomal aberrations, and sister chromatid exchanges. Although it is premature to declare a cause and effect relationship between the carcinogenic activity of metals and their ability to induce one or more lesions in DNA, strong evidence is emerging to suggest such a relationship. Low concentrations of metals induce the appearance of DNA lesions, such as strand breaks and crosslinks, or induce sister chromatid exchanges or DNA repair synthesis. Assays based upon these events constitute extremely sensitive probes for genotoxic effects of metals and their compounds. These effects of metals on DNA are consistent with the currently accepted mechanism of chemical carcinogenesis, allowing the acquisition and propagation of altered DNA function. The lack of complete information on the activity of metals in producing DNA lesions allow only preliminary conclusions to be drawn. Certain compounds containing potentially or actually carcinogenic elements, such as Ni, Be, As, Cr, Cd, and to a minor extent Pb, have yielded positive responses in one or more DNA lesion assays. At relatively nontoxic levels of Ni and Cr, considerable evidence suggests that multiple types of DNA lesions are induced.     

A systematic molecular dynamics study of nearest-neighbor effects on base pair and base pair step conformations and fluctuations in B-DNA

It is well recognized that base sequence exerts a significant influence on the properties of DNA and plays a significant role in protein–DNA interactions vital for cellular processes. Understanding and predicting base sequence effects requires an extensive structural and dynamic dataset which is currently unavailable from experiment. A consortium of laboratories was consequently formed to obtain this information using molecular simulations. This article describes results providing information not only on all 10 unique base pair steps, but also on all possible nearest-neighbor effects on these steps. These results are derived from simulations of 50–100 ns on 39 different DNA oligomers in explicit solvent and using a physiological salt concentration. We demonstrate that the simulations are converged in terms of helical and backbone parameters. The results show that nearest-neighbor effects on base pair steps are very significant, implying that dinucleotide models are insufficient for predicting sequence-dependent behavior. Flanking base sequences can notably lead to base pair step parameters in dynamic equilibrium between two conformational sub-states. Although this study only provides limited data on next-nearest-neighbor effects, we suggest that such effects should be analyzed before attempting to predict the sequence-dependent behavior of DNA.     

Direct inhibition of excision/synthesis DNA repair activities by cadmium: analysis on dedicated biochips

The well established toxicity of cadmium and cadmium compounds results from their additive effects on several key cellular processes, including DNA repair. Mammalian cells have evolved several biochemical pathways to repair DNA lesions and maintain genomic integrity. By interfering with the homeostasis of redox metals and antioxidant systems, cadmium promotes the development of an intracellular environment that results in oxidative DNA damage which can be mutagenic if unrepaired. Small base lesions are recognised by specialized glycosylases and excised from the DNA molecule. The resulting abasic sites are incised, and the correct sequences restored by DNA polymerases using the opposite strands as template. Bulky lesions are recognised by a different set of proteins and excised from DNA as part of an oligonucleotide. As in base repair, the resulting gaps are filled by DNA polymerases using the opposite strands as template. Thus, these two repair pathways consist in excision of the lesion followed by DNA synthesis. In this study, we analysed in vitro the direct effects of cadmium exposure on the functionality of base and nucleotide DNA repair pathways. To this end, we used recently described dedicated microarrays that allow the parallel monitoring in cell extracts of the repair activities directed against several model base and/or nucleotide lesions. Both base and nucleotide excision/repair pathways are inhibited by CdCl?, with different sensitivities. The inhibitory effects of cadmium affect mainly the recognition and excision stages of these processes. Furthermore, our data indicate that the repair activities directed against different damaged bases also exhibit distinct sensitivities, and the direct comparison of cadmium effects on the excision of uracile in different sequences even allows us to propose a hierarchy of cadmium sensibility within the glycosylases removing U from DNA. These results indicate that, in our experimental conditions, cadmium is a very potent DNA repair poison.     

Shape and compaction of Escherichia coli nucleoids

The genomic DNA in cells of Escherichia coli is localized in one or two compact, phase-like regions with characteristic shapes. Nucleoids undergo progressive changes in shape and compaction in the presence of drugs such as chloramphenicol or puromycin. Forces which influence nucleoid shape and compaction are reviewed, with particular emphasis on crowding effects of the cytoplasm and confinement effects of the cell envelope. Based in part on the theory of Kornyshev and Leikin for interaction between DNA duplexes, the folding of DNA caused by binding of DNA-associated proteins is suggested to antagonize DNA condensation and, thereby, increase access to DNA sequences. These views are incorporated into a working model for nucleoid organization.     

The structure of methylated xanthines in relation to their effects on DNA synthesis and cell lethality in nitrogen mustard-treated cells.

The variation in cellular response to alkylated xanthines possessing different side chains has been used to evaluate more fully the effect of caffeine on both survival and DNA synthesis in cells with DNA damage. A correlation is observed between the ability of these xanthines to reverse the inhibitory effects of nitrogen mustard damage on DNA synthesis and their ability to enhance nitrogen mustard lethality in human HT-29 cells. These findings are consistent with our theory that regulation of damaged replicon initiation protects against potentially lethal damage in the form of unrepaired DNA alkylations. Enhancement of nitrogen mustard lethality is observed to have a maximum limit, which can be reduced by highly toxic xanthine concentrations. The lethal effects of xanthines alone at higher concentrations are unrelated to the effects of caffeine specific to nitrogen mustard treated cells, and appear to be related to an immediate reduction in thymidine incorporation most likely caused by inhibition of other enzyme systems influencing DNA synthesis such as de novo and salvage pathways for purine biosynthesis.     

Interactions between distamycin A analogs bound to DNA

The experimental binding isotherms of the distamycin A analog to 8 natural and synthetic DNAs were analyzed. The shapes of binding isotherms suggest that the bound ligand molecule induces transitions of DNA (B-form) into two perturbated conformation states. These transitions are responsible for the existence of positive and negative cooperative effects on binding of distamycin analogs to DNA. At low levels of binding positive cooperative effects play a dominating role whereas at high levels of binding negative cooperative effects are observed. These cooperative effects can be described by the aid of a potential of pairwise interactions between nearest neighbour bound antibiotic molecules. A detailed analysis of experimental binding isotherms shows that characteristic distances over which these interactions are extended depend on the AT content of DNA. The energetical and structural parameters characterising the allosteric transitions of DNA to the perturbated states are obtained.     

DNA damage induced hyperphosphorylation of replication protein A. 2. Characterization of DNA binding activity, protein interactions, and activity in DNA replication and repair

Replication protein A (RPA) is a heterotrimeric protein consisting of 70-, 34-, and 14- kDa subunits that is required for many DNA metabolic processes including DNA replication and DNA repair. Using a purified hyperphosphorylated form of RPA protein prepared in vitro, we have addressed the effects of hyperphosphorylation on steady-state and pre-steady-state DNA binding activity, the ability to support DNA repair and replication reactions, and the effect on the interaction with partner proteins. Equilibrium DNA binding activity measured by fluorescence polarization reveals no difference in ssDNA binding to pyrimidine-rich DNA sequences. However, RPA hyperphosphorylation results in a decreased affinity for purine-rich ssDNA and duplex DNA substrates. Pre-steady-state kinetic analysis is consistent with the equilibrium DNA binding and demonstrates a contribution from both the k(on) and k(off) to achieve these differences. The hyperphosphorylated form of RPA retains damage-specific DNA binding, and, importantly, the affinity of hyperphosphorylated RPA for damaged duplex DNA is 3-fold greater than the affinity of unmodified RPA for undamaged duplex DNA. The ability of hyperphosphorylated RPA to support DNA repair showed minor differences in the ability to support nucleotide excision repair (NER). Interestingly, under reaction conditions in which RPA is maintained in a hyperphosphorylated form, we also observed inhibition of in vitro DNA replication. Analyses of protein-protein interactions bear out the effects of hyperphosphorylated RPA on DNA metabolic pathways. Specifically, phosphorylation of RPA disrupts the interaction with DNA polymerase alpha but has no significant effect on the interaction with XPA. These results demonstrate that the effects of DNA damage induced hyperphosphorylation of RPA on DNA replication and DNA repair are mediated through alterations in DNA binding activity and protein-protein interactions.     

Improved quantitation of DNA curvature using ligation ladders.

It is often desirable to estimate accurately the local shape of DNA molecules. Such measurements are useful in understanding the intrinsic contribution of DNA sequence to curvature, as well as in assessing the effects of chemical modifications. We have been investigating the effects of asymmetric phosphate neutralization on DNA shape using the well-characterized ligation ladder approach developed by Crothers and co-workers [D.M.Crothers and J.Drak (1992) Meth. Enzymol.,212, 46-71]. This technique is remarkably sensitive to differences in DNA shape. We now report a general quantitative assay of DNA curvature that we have validated using a set of phased A(5)tract standards. This approach allows simultaneous estimation of helix axis deflection magnitude and direction when a test sequence is monitored in at least three phasings relative to a reference A(5-6)tract in short DNA duplexes. Analysis using this improved approach confirms our published data on DNA curvature due to electrostatic effects.     

50-Hertz electromagnetic fields induce gammaH2AX foci formation in mouse preimplantation embryos in vitro

Effects of electromagnetic fields (EMFs) on DNA damage in mammals are still controversial. In the present study, the effects of EMFs on DNA damage in preimplantation mouse embryos in vitro were investigated by using gammaH2AX foci formation, a new sensitive indicator for detecting DNA double-strand breaks (DSBs). The data obtained demonstrated that EMFs decreased the cleavage rate of preimplantation mouse embryos. This decreasing effect of EMFs was related to the DNA-damaging effect indicated by the induction of gammaH2AX foci formation in preimplantation mouse embryos. The inducing effects of EMFs on gammaH2AX foci formation could be inhibited by the treatment of noise MFs or wortmannin, a phosphatidylinositol 3-kinase (PI3K) family inhibitor. Furthermore, the data obtained also showed that EMFs could activate the DNA damage-repair mechanism by recruiting repair factor Rad50 to the damaged DNA sites to repair the corresponding DNA damage. These findings suggest that EMFs could cause DNA damage in preimplantation embryos in vitro and that the adverse effects of EMFs on development might at least partly act through DNA damage. The DNA damage induced by EMFs could be at least partly repaired by the natural activation of DNA damage-repair mechanism or prevented by the simultaneous treatment of noise magnetic fields.     

Sensitivity of human type II topoisomerases to DNA damage: stimulation of enzyme-mediated DNA cleavage by abasic, oxidized and alkylated lesions

Type II topoisomerases are essential enzymes that are also the primary cellular targets for a number of important anticancer drugs. These drugs act by increasing levels of topoisomerase II-mediated DNA cleavage. Recent studies indicate that endogenous forms of DNA damage, such as abasic sites and base mismatches, also stimulate the DNA scission activity of the enzyme. To extend our understanding of how type II topoisomerases react to DNA damage, the effects of abasic sites, and oxidized and alkylated bases on DNA cleavage mediated by human topo-isomerase IIα and β were determined. Based on experiments that incorporated random abasic sites into plasmid DNA, human type II enzymes can locate lesions even within a background of several thousand undamaged base pairs. As determined by experiments that utilized site-specific forms of DNA lesions, oxidized or monoalkylated purines that allow base pairing and induce little distortion in the double helix have modest effects on topoisomerase II-mediated DNA cleavage. In contrast, 1,N⁶-ethenoadenine, a bulky lesion that disrupts base pairing, enhanced DNA cleavage ~10-fold. 1,N⁶-Ethenoadenine is the first lesion found to rival the stimulatory effects of apurinic sites on the DNA scission activity of eukaryotic type II topoisomerases.     

Micronutrient special issue: Coenzyme Q(10) requirements for DNA damage prevention

Coenzyme Q(10) (CoQ(10)) is an essential component for electron transport in the mitochondrial respiratory chain and serves as cofactor in several biological processes. The reduced form of CoQ(10) (ubiquinol, Q(10)H(2)) is an effective antioxidant in biological membranes. During the last years, particular interest has been grown on molecular effects of CoQ(10) supplementation on mechanisms related to DNA damage prevention. This review describes recent advances in our understanding about the impact of CoQ(10) on genomic stability in cells, animals and humans. With regard to several in vitro and in vivo studies, CoQ(10) provides protective effects on several markers of oxidative DNA damage and genomic stability. In comparison to the number of studies reporting preventive effects of CoQ(10) on oxidative stress biomarkers, CoQ(10) intervention studies in humans with a direct focus on markers of DNA damage are limited. Thus, more well-designed studies in healthy and disease populations with long-term follow up results are needed to substantiate the reported beneficial effects of CoQ(10) on prevention of DNA damage.     

Nickel chloride inhibits the DNA repair of UV-treated but not methyl methanesulfonate-treated chinese hamster ovary cells

Nickel, a human carcinogen, has been shown to enhance the cytotoxicity, mutagenicity, and sister-chromatid exchanges (SCE) induced by ultraviolet (UV) light but not by methyl methanesulfonate (MMS). To verify that the cocytotoxicity and cogenotoxicity of nickel are correlated with its inhibition on DNA repair, the effects of nickel on the DNA repair induced by UV and by MMS have been investigated. Our analyses of DNA repair of single-strand breaks by alkaline elution and alkaline sucrose sedimentation indicate that nickel inhibited the DNA repair in UV-treated, but not in MMS-treated cells. Therefore, the inhibition of DNA repair seems to play an important role in the cocytotoxicity and comutagenicity of nickel. However, the inhibition of DNA repair seems not to play a decisive role in enhancing SCE, because we have previously shown that arsenite inhibits the UV-induced DNA repair, but has no enhancing effect on the UV-induced SCE. Our results also show that nickel had obvious inhibitory effects on DNA ligation and postreplication repair, but had no apparent effect on nucleotide excision and DNA polymerization in the UV repair. The results of the DNA ligation inhibition by nickel in UV but not in MMS repair suggest that different ligases are used in the DNA repair of UV- and MMS-induced damages.     

Polymorphisms in DNA repair and environmental interactions

The repair of damage to DNA is critical to the survival of a cell. However, not all organisms nor all individuals express a similar response to challenges to their genetic material. Numerous polymorphisms in genes involved in DNA repair have been found in individuals with DNA repair-related disease as well as in the general population. Studies of these variants are critical in understanding the response of the cell to DNA damage. In some cases, these changes predispose the carrier to a greatly increased risk of cancer. In other cases, the effects are subtler and depend on interactions between the alleles of several genes, or with environmental factors. Consequently, the health effects of exposure to genotoxic or carcinogenic compounds or agents can depend on the variations in these genes. This review will highlight some of the effects that variants, found in many of the genes involved in human DNA repair pathways, have on the response to damage, and their role in susceptibility of the cell and organism to environmental genotoxins. This review will concentrate on the mismatch repair, nucleotide repair, base excision repair, strand break repair, and direct alkyl repair pathways.     

Effects of the stereochemical configuration on the interaction of some daunomycin derivatives with DNA

Four stereoisomeric daunomycin derivatives, characterized by the absence of the methoxyl group in position 4, have been examined for effects on the thermal denaturation of calf thymus DNA and for their ability to bind to DNA, in order to delineate the antibiotic steric features affecting the binding ability. The major conclusions are: (a) the inverted configuration at positions 7 and 9 markedly decreases the DNA binding; (b) the consequences of the above stereochemical inversion are more critical that the inversion of configuration at position 1 of the amino sugar; (c) in general, the effects on the in vitro activity of nucleic acid polymerizing enzymes are consistent with the DNA interaction properties. The structure-activity correlations deduced from these studies are in agreement with earlier findings relating to antitumor activity.     

Induced topological changes in DNA complexes: influence of DNA sequences and small molecule structures

Heterocyclic diamidines are compounds with antiparasitic properties that target the minor groove of kinetoplast DNA. The mechanism of action of these compounds is unknown, but topological changes to DNA structures are likely to be involved. In this study, we have developed a polyacrylamide gel electrophoresis-based screening method to determine topological effects of heterocyclic diamidines on four minor groove target sequences: AAAAA, TTTAA, AAATT and ATATA. The AAAAA and AAATT sequences have the largest intrinsic bend, whereas the TTTAA and ATATA sequences are relatively straight. The changes caused by binding of the compounds are sequence dependent, but generally the topological effects on AAAAA and AAATT are similar as are the effects on TTTAA and ATATA. A total of 13 compounds with a variety of structural differences were evaluated for topological changes to DNA. All compounds decrease the mobility of the ATATA sequence that is consistent with decreased minor groove width and bending of the relatively straight DNA into the minor groove. Similar, but generally smaller, effects are seen with TTTAA. The intrinsically bent AAAAA and AAATT sequences, which have more narrow minor grooves, have smaller mobility changes on binding that are consistent with increased or decreased bending depending on compound structure.